Some embodiments of a fluid expansion system can be used with the working fluid in a Rankine cycle. For example, the fluid expansion system can be used in a Rankine cycle to recover heat from one of a number of commercial applications and to convert that heat energy into electrical energy. In partic
Some embodiments of a fluid expansion system can be used with the working fluid in a Rankine cycle. For example, the fluid expansion system can be used in a Rankine cycle to recover heat from one of a number of commercial applications and to convert that heat energy into electrical energy. In particular embodiments, the fluid expansion system may include a turbine generator apparatus to generate electrical energy and a liquid separator arranged upstream of the turbine generator apparatus.
대표청구항▼
1. A generator system for use in a Rankine cycle, comprising: a turbine generator apparatus including an inlet conduit to direct a working fluid in a Rankine cycle toward a turbine wheel that is rotatable in response to expansion of the working fluid;an electrical energy generator having a stator an
1. A generator system for use in a Rankine cycle, comprising: a turbine generator apparatus including an inlet conduit to direct a working fluid in a Rankine cycle toward a turbine wheel that is rotatable in response to expansion of the working fluid;an electrical energy generator having a stator and a rotor, wherein the rotor is coupled to the turbine wheel so as to rotate when the turbine wheel rotates in response to expansion of the working fluid flowing from proximate an inlet side to an outlet side of the turbine wheel, the electrical energy generator is disposed adjacent to the outlet side of the turbine wheel, and the inlet conduit is in fluid communication with the electric energy generator to direct working fluid from the turbine wheel in direct contact with the electric energy generator to cool the electric energy generator;a liquid separator that receives the working fluid comprising a liquid state portion and a gaseous state portion and that separates the liquid state portion of the working fluid from the gaseous state portion of the working fluid, the liquid separator being connected in the Rankine cycle upstream of the turbine generator apparatus and downstream of a heat exchanger, the liquid separator in direct fluid communication with the turbine generator apparatus so that the gaseous state portion of the working fluid is directed from an outlet of the liquid separator directly to the inlet conduit of the turbine generator after separation of the liquid state portion;a flow valve arranged in the Rankine cycle upstream of the turbine generator apparatus so as to selectively close the flow of the working fluid to the turbine generator apparatus; anda bypass valve arranged in the Rankine cycle to selectively open the flow of the working fluid to bypass the turbine generator apparatus, wherein the flow valve and the bypass valve are mechanically coupled to the same actuator device to operate in unison. 2. The generator system of claim 1, wherein the liquid separator comprises a cyclone separator device. 3. The generator system of claim 2, wherein at least a component of the cyclone separator mechanically rotates to centrifugally separate the liquid state portion of the working fluid from the gaseous state portion of the working fluid. 4. The generator system of claim 1, wherein the liquid separator comprises a coalescing membrane device. 5. The generator system of claim 1, wherein the liquid separator is connected in the Rankine cycle upstream of the turbine generator apparatus so that the working fluid is in a heated and pressurized state when received by the liquid separator. 6. The generator system of claim 5, wherein the liquid separator directs the liquid state portion to a low pressure reservoir in the Rankine cycle and directs the gaseous state portion to the inlet conduit of the turbine generator apparatus. 7. The generator system of claim 6, wherein the liquid separator serves as a reservoir volume disposed upstream of the turbine generator apparatus in the Rankine cycle so as to maintain flow stability to the turbine generator apparatus in the event of a burst of flow from upstream of the turbine generator apparatus. 8. The generator system of claim 1, further comprising a system package that houses the turbine generator apparatus, the liquid separator, a fluid pump device, and a low pressure reservoir for the working fluid, the system package having a width of less than about 72 inches and a height of less than about 80 inches so as to fit through a double-door passage. 9. The generator system of claim 1, wherein the Rankine cycle is an organic Rankine cycle. 10. The generator system of claim 1, comprising a body casing configured to extend around and enclose both the turbine generator apparatus and the electrical energy generator. 11. The generator system of claim 1, comprising an actuator device, wherein the flow valve is linked to and the bypass valve so that actuation of one of the flow valve or the bypass valve results in actuation of the other one of the flow valve or the bypass valve are both coupled to the actuator device. 12. The generator system of claim 1, wherein the actuator device comprises at least one of a servo actuator, a hydraulic actuator, a pneumatic actuator, or a hand-operated lever, or any combination thereof. 13. The generator system of claim 1, wherein the actuator device is configured to open the flow valve while closing the bypass valve or to close the flow valve while opening the bypass valve. 14. A method comprising: directing heated and pressurized working fluid comprising a liquid state portion and a gaseous state portion in a Rankine cycle from a heat exchanger to a liquid separator, the liquid separator including an outlet for the gaseous state portion arranged in the Rankine cycle upstream of a turbine generator apparatus and in direct fluid communication to an inlet conduit of the turbine generator apparatus;separating the liquid state portion of the heated and pressurized working fluid from the gaseous state portion of the heated and pressurized working fluid;directing the gaseous state portion of the working fluid directly from the outlet for the gaseous state portion of the liquid separator to the inlet conduit of the turbine generator apparatus and toward a turbine wheel that is rotatable in response to expansion of the working fluid;directing the liquid state portion of the working fluid from the liquid separator to a secondary reservoir in the Rankine cycle, wherein the secondary reservoir does not comprise a heat exchange device; anddirecting the liquid state portion from the secondary reservoir to a low pressure reservoir in the Rankine cycle, wherein the low pressure reservoir does not comprise a heat exchange device. 15. The method of claim 14, wherein the liquid separator comprises a cyclone separator device, the method further comprising rotating at least a component of the cyclone separator to centrifugally separate the liquid state portion of the working fluid from the gaseous state portion of the working fluid. 16. The method of claim 14, further comprising maintaining flow stability to the turbine generator apparatus in the event of a burst of flow from upstream of the turbine generator apparatus. 17. The method of claim 14, further comprising rotating the turbine wheel of the turbine generator apparatus using a turbine in response to expansion of the working fluid flowing from proximate an inlet side to an outlet side of the turbine wheel. 18. The method of claim 17, further comprising generating electrical energy from the rotation of the turbine wheel, the turbine wheel being coupled to a rotor of an electrical energy generator, the electrical energy generator disposed adjacent to the outlet side of the turbine wheel. 19. A generator system for use in a Rankine cycle, comprising: a low pressure reservoir for a working fluid of a Rankine cycle, wherein the low pressure reservoir does not comprise a heat exchange device;a pump device to pressurize the working fluid delivered from the low pressure reservoir;a liquid separator to separate a liquid state portion of the working fluid from a gaseous state portion of the working fluid, the liquid separator being arranged in the Rankine cycle between a heat exchanger and a turbine generator, upstream of the turbine generator and downstream of the pump device and the heat exchanger so as to receive the pressurized working fluid from the pump device;a secondary reservoir fluidly coupled to the liquid separator and the low pressure reservoir, wherein the secondary reservoir consists of an inlet coupled to the liquid separator, an outlet coupled to the low pressure reservoir, and a chamber to contain the liquid state portion, and the secondary reservoir does not comprise a heat exchange device;a turbine generator apparatus that generates electrical energy in response to expansion of the working fluid, the turbine generator apparatus being arranged in the Rankine cycle downstream of the liquid separator so that the gaseous state portion of the working fluid is directed from an outlet of the liquid separator directly to an inlet conduit of the turbine generator apparatus after separation of the liquid state portion;a conduit to direct the working fluid through the turbine generator apparatus, wherein the working fluid is configured to remove heat from the turbine generator apparatus;a flow valve arranged in the Rankine cycle upstream of the turbine generator apparatus so as to selectively close the flow of the working fluid to the turbine generator apparatus;a bypass valve arranged in the Rankine cycle to selectively open a bypass conduit that directs the working fluid toward the low pressure reservoir without passing into the turbine generator apparatus, wherein the flow valve and the bypass valve are mechanically coupled to the same actuator device one another to operate in unison; anda transportable system package that houses the low pressure reservoir, the pump device, the liquid separator, the turbine generator apparatus, the flow valve, and the bypass valve. 20. The generator system of claim 19, wherein the secondary reservoir comprises a level switch configured to provide an indication of a level of the liquid state portion in the secondary reservoir.
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